A Model of Nonlocal Quantum Electrodynamics; Time's Arrow and Epr-Like Quantum Correlation

Abstract: A recent experiment with squeezed light has shown that two-photon absorption by an atom can occur with a linear intensity dependence. We point out that this result verifies a prediction made by us a decade back from an analysis of a non-local model of Quantum Electrodynamics. This model had earlier been proposed by us in an ad hoc manner to interpret certain features of multiphoton double ionisation and above-threshold ionisation in an atom placed in a strong laser field ; in this paper we show that the model … Show more

“…To make the present paper self-contained, we briefly recapitulate here how the time's arrow appears in the theory as a necessary condition for conservation of energy in the atomic level. (See [1] for details.) A matrix element for matter-radiation interaction with the non-local electromagnetic field potential A(x, x ′ ) where x≡(r,t) is typically of the form…”

“…After Fourier expanding A in two sets of photon modes (see, e.g. [6]), the time integration over dt gives us the energyconserving delta-function δ(E f , E i +hω +hω ′ ) in the correlated two-photon absorption process (see below ; this is one of the new results in [1]). Formally, this time integration runs from t = −∞ to t = +∞.…”

“…We may ask the question from the opposite viewpoint : what happens in a reaction if one or more of the reactants/products travel backward in time ? According to [1], the answer is simple ; energy will not be conserved, hence mass↔energy conversion must occur in such reactions. (Of course, the precise time interval between the "start" of the reaction and the mass↔energy conversion depends on the particular characteristics in the process involved ; for example, positron-electron annihilation can take place either instantaneously or after positronium formation, depending on the collision geometry.…”

“…(This invariance is not quite self-evident, as we remember that the CPT theorem is supposed to be valid for local field theories only ; our work seems to have broadened its scope.) c As shown in [1], however, we have to pay a price for it ; the correlation with the "past" is to be understood in an EPR-like sense and not in a Lorentz invariant sense, if we are to maintain energy conservation. (This serves to remind us that quantum mechanics and special relativity have always been strange bedfellows.)…”

“…Some time ago [1] we obtained a result that matter fields possess a non-local U(1) gauge transformation symmetry that necessitates invoking a non-local electromagnetic field, and that a non-thermodynamic arrow of time at the quantum (atomic) level is enforced upon us as a necessary condition for conservation of energy in matter-radiation interactions. Based upon this result, it was subsequently predicted [2] that the spectrum of a blackbody radiation passing through gaseous matter would show an apparent deviation from the Planck formula.…”

Father Time Ii: A Physical Basis Behind Feynman's Idea of (Anti)particles Moving Backward in Time, and an Extension of the CPT Theorem to Include Nonlocal Gauge Fields

“…To make the present paper self-contained, we briefly recapitulate here how the time's arrow appears in the theory as a necessary condition for conservation of energy in the atomic level. (See [1] for details.) A matrix element for matter-radiation interaction with the non-local electromagnetic field potential A(x, x ′ ) where x≡(r,t) is typically of the form…”

“…After Fourier expanding A in two sets of photon modes (see, e.g. [6]), the time integration over dt gives us the energyconserving delta-function δ(E f , E i +hω +hω ′ ) in the correlated two-photon absorption process (see below ; this is one of the new results in [1]). Formally, this time integration runs from t = −∞ to t = +∞.…”

“…We may ask the question from the opposite viewpoint : what happens in a reaction if one or more of the reactants/products travel backward in time ? According to [1], the answer is simple ; energy will not be conserved, hence mass↔energy conversion must occur in such reactions. (Of course, the precise time interval between the "start" of the reaction and the mass↔energy conversion depends on the particular characteristics in the process involved ; for example, positron-electron annihilation can take place either instantaneously or after positronium formation, depending on the collision geometry.…”

“…(This invariance is not quite self-evident, as we remember that the CPT theorem is supposed to be valid for local field theories only ; our work seems to have broadened its scope.) c As shown in [1], however, we have to pay a price for it ; the correlation with the "past" is to be understood in an EPR-like sense and not in a Lorentz invariant sense, if we are to maintain energy conservation. (This serves to remind us that quantum mechanics and special relativity have always been strange bedfellows.)…”

“…Some time ago [1] we obtained a result that matter fields possess a non-local U(1) gauge transformation symmetry that necessitates invoking a non-local electromagnetic field, and that a non-thermodynamic arrow of time at the quantum (atomic) level is enforced upon us as a necessary condition for conservation of energy in matter-radiation interactions. Based upon this result, it was subsequently predicted [2] that the spectrum of a blackbody radiation passing through gaseous matter would show an apparent deviation from the Planck formula.…”

Father Time Ii: A Physical Basis Behind Feynman's Idea of (Anti)particles Moving Backward in Time, and an Extension of the CPT Theorem to Include Nonlocal Gauge Fields

On nonlocal complex Maxwell equations and wave motion in electrodynamics and dielectric media

Quantum interference in the hydrogen molecule with squeezed light